EP4192804A1 - Device and method for producing methanol from carbon dioxide - Google Patents

Abstract

The invention relates to a device for producing methanol from carbon dioxide, comprising a first circulation process (1) for water and methanol, comprising an absorption stage (5) for carbon dioxide from process gases, a desorption stage (6) with a hydrogen supply (16), a heat exchanger (7) between the absorption stage and the desorption stage, an outlet (19) for water and methanol, a circulation pump (8), as well as an expansion throttle (9); a second circulation process (2) for methanol, water, carbon dioxide and hydrogen, comprising the desorption stage (6), a liquid-gas phase separation stage (22) with a return (23) for liquid phases to the desorption stage as well as a gas outlet (15) and an inlet from or into the desorption stage; as well as a third circulation process (3) for carbon dioxide and water, comprising a methanol synthesis reactor (26), the liquid-gas phase separation stage (22), a second heat exchanger (30), a gas outlet (31) between the methanol synthesis reactor and the second heat exchanger, as well as a fan (32).

Description

Device and method for the production of methanol

carbon dioxide

The invention relates to a device and a method for producing methanol from carbon dioxide according to the first or the thirteenth claim.

One of the main causes of global climate change is the emission of greenhouse gases such as carbon dioxide, CO2, from technical processes such as B. Combustion processes or in the production of z. B. cement or steel into the Earth's atmosphere. One possible approach to reducing CCh emissions is to reduce the use of fossil fuels in favor of increasing the use of renewable energies. However, renewable energies are often available as electrical energy, and this is the only one that is important, especially in energy-intensive processes such as e.g. B. in the production of cement or steel or in long-distance mobility does not represent an alternative to chemical energy sources, even in the long term.

Another approach to reducing emissions in the carbon dioxide balance is offered by the so-called Carbon Capture and Utilization (CCU) Technologies . They extract the resulting CO2 from emissions, especially from combustion exhaust gases, or the atmosphere and convert it using renewable energy in chemical processes into carbon-containing fuels and chemicals.

The production of methanol is one of the most important CCU applications due to its relevance as a basic chemical. With a global production of over 110 million tons per year, methanol is required to manufacture products, chemical intermediates, plastics and fine chemicals. Also known are methods for the conversion of methanol into hydrocarbon fuels or into the use of methanol itself as a fuel.

For example, WO 2001/17936 A2 discloses a method and a plant for synthesizing methanol from a gas mixture of hydrogen, carbon monoxide and carbon dioxide. The gas mixture is converted to methanol under pressure in at least one synthesis stage, the gas mixture intended for use in a catalyst-filled methanol synthesis reactor being heated in an additional trimmer heater directly before being added to said methanol synthesis reactor. In this prior art, the desired goal of preheating was to save heat exchanger surface area and/or to increase the yield, with special consideration of the variable catalyst activity.

Proceeding from this, one object of the invention is to propose a device for producing methanol from carbon dioxide, which maps an entire methanol synthesis process from the extraction of carbon dioxide from gas mixtures to the generation of a methanol stream.

Furthermore, a method for the production of methanol from carbon dioxide with this entire methanol synthesis process is to be proposed.

The object is with a device and a method according to claim 1 or. 13 solved . Subclaims referring back to this reflect advantageous embodiments.

The solution to the problem includes a device and a method for producing methanol from a CO2-containing gas mixture such as a combustion exhaust gas or a process gas and hydrogen. A proposed device for producing methanol from carbon dioxide comprises three cycle processes.

The first cycle process with a first circulating line for a circulating first mixture of water and methanol comprises: i) an absorption stage for carbon dioxide with a passage for a gas containing carbon dioxide, ii) a desorption stage for carbon dioxide with an inlet for hydrogen, iii) a first heat exchanger between the absorption stage and the desorption stage, with the circulating line crossing in the heat exchanger, iv) an outlet for the first mixture of water and methanol between the desorption stage and the first heat exchanger, v) a circulation pump between the absorption stage and the desorption stage, and vi ) an expansion choke between the first heat exchanger and the adsorption stage .

The second circulation process with a second circulating line for a circulating second mixture of methanol, water, carbon dioxide and hydrogen comprises: i) a desorption stage for carbon dioxide with the feed for hydrogen and ii) a first liquid-gas phase separation stage with a return for liquid phases of the methanol and the water to the desorption stage as part of the second recirculating line and a gas outlet and an inlet for a liquid-gas phase mixture from the desorption stage. The third cycle process with a third circulating line for a circulating third mixture of carbon dioxide and hydrogen comprises: i) a methanol synthesis reactor with cooling, ii) the first liquid-gas phase separation stage, the gas outlet opening into the third circulating line and the third recirculating line opens into the inlet, iii) a second heat exchanger between the methanol synthesis reactor and the first liquid-gas phase separation stage, the third recirculating line crossing in the second heat exchanger, iv) a gas outlet in the third recirculating line between the methanol synthesis reactor and the second heat exchanger, v) a fan between the second heat exchanger and the inlet.

A proposed process for producing methanol from carbon dioxide comprises at least the following process steps: a) providing a device for producing methanol from carbon dioxide, as described above, including optional configurations, b) passing a carbon dioxide-containing gas through the absorption stage, the carbon dioxide at a pressure between 1 bar and 10 bar (limit values included) and a temperature between -30 °C and 10 °C (limit values included) by a liquid first mixture of water and methanol in the first cycle process, c) compression and temperature control of the first mixture with the carbon dioxide in the circulating zpumpe or. in the first heat exchanger of the first cycle process to a pressure between 40 bar and 50 bar (limit values each included) and a temperature between 100 ° C and 180 ° C (limit values each included), d) introduction of the compressed and temperature-controlled first mixture with the carbon dioxide in the desorption stage, with the carbon dioxide from desorbed from the first mixture and taken from the first cycle process and with the addition of hydrogen from a circulating second mixture of methanol, water, carbon dioxide and hydrogen in the second cycle process at a pressure between 40 bar and 50 bar (limit values of each inclusive) and one Temperature between 100 ° C and 180 ° C (limit values included), e) forwarding of the carbon dioxide in the second cycle process in the first liquid-gas phase separation stage, in which a gas mixture of carbon dioxide and hydrogen selectively as a third mixture from the second is diverted into the third cycle process, f) heating of the Gasgem ic in the second heat exchanger in the third cycle process to a temperature between 210 ° C and 260 ° C (limit values included in each case), g) introduction of the temperature-controlled gas mixture into the methanol synthesis reactor and partial conversion of the third mixture into methanol and water, h) recirculation of the third Mixture, the methanol and the water through the second heat exchanger into the first liquid-gas phase separation stage, i) separation of the liquid components of the mixture, the methanol and the water in the first liquid-gas phase separation stage and recycling them via the second cycle process into the desorption stage and j) continuous branching off of a mixture of water and methanol from the desorption stage. A basic idea of the solution is to integrate the separation of carbon dioxide from an exhaust gas or another gas containing carbon dioxide into the cycle processes of the methanol synthesis process. A mixture of methanol and water, a liquid absorbent that is already present in the context of the subsequent methanol synthesis, is used to separate carbon dioxide. It is also proposed to condense the methanol formed in the methanol synthesis together with water and to make it available at least partially for the separation of the carbon dioxide from the exhaust gas or other gases containing carbon dioxide.

Another basic idea of the solution is to desorb the carbon dioxide absorbed into the mixture of methanol and water from the mixture using hydrogen as a flushing gas and then to feed it together with the hydrogen to the methanol synthesis.

Furthermore, it is preferably proposed to carry out the methanol synthesis and the desorption of the carbon dioxide from the mixture of methanol and water at the same pressure level.

In a technical process such as B. a combustion process or a manufacturing process of z. B. Integrated with cement or steel, another advantage lies not only in the reduction of the CO2 emissions of the technical process, but also in the direct integration of a hydrogen electrolysis for the provision of the aforementioned flushing gas in the overall process. This also reduces the costs for the device and operation in an advantageous manner in comparison to the conventional method for methanol synthesis in combination with a CCh separation. The particular advantage of the invention is that carbon dioxide is continuously separated from a flue gas stream or a process gas stream at low pressures, regardless of the respective carbon dioxide content (typically 10 to 90% by volume). These flue gas streams or process gas streams come from industrial and non-industrial processes such as:

- Biogas with carbon concentrations typically of 40-50 vol. -% ,

- Flue gas from an industrial process such as a power plant, chemical process, steel making, cement making and the like

- Flue gas from a waste incineration plant.

- Synthesis gas containing carbon dioxide from biomass gasification.

The invention is explained in more detail with reference to exemplary embodiments from the following figures and descriptions. All of the features shown and their combinations are not limited to these exemplary embodiments and their configurations. Rather, these should be viewed as representative of further possible configurations that are not explicitly shown as exemplary embodiments and can be combined. Show it

Fig. l schematically a first exemplary embodiment of a device for the production of methanol from carbon dioxide, comprising three cycle processes,

Fig. 2 shows schematically the first exemplary embodiment according to FIG. l, but with additional temperature control means for the combustion exhaust gas or the process gas and an additional liquid phase return to the desorption stage, Fig .3 schematically shows a second exemplary embodiment from a device for the production of methanol from carbon dioxide, comprising three cycle processes and

Fig. 4 schematically shows a flow chart (process FLOW diagram) of the method in a device according to the one shown in FIG. l embodiment shown.

The ones shown in Fig. 1 to 3 for producing methanol from carbon dioxide comprise at least three circulatory processes 1, 2 and 3. The embodiments shown are described below by way of example with reference to FIG. 1 shown, while optional refinements are also illustrated with reference to FIGS. 2 and 3 are explained in more detail.

A first circulatory process 1 has a first circulating line 4 for a circulating first mixture of water and methanol. In this, an absorption stage 5 and a desorption stage 6 for carbon dioxide, at least one first heat exchanger 7, a circulating pump 8 and an expansion throttle 9 are provided. The circulating line crosses between the absorption stage and a desorption stage in the heat exchanger.

The circulating line 4 of the first circulation process runs through the absorption stage 5 , preferably from top to bottom, followed by a serial arrangement of circulation pump 8 and first heat exchanger 7 , before it opens into the desorption stage 6 . Like the adsorption stage, the desorption stage is preferably penetrated from top to bottom, followed by a passage through the first heat exchanger 7 and an expansion throttle 9 back to the aforementioned absorption stage. The passages through the absorption stage and the desorption stage are part of the circuit of the first circulatory process . This also intersects in the first heat exchanger, suitable for heat transfer between the intersecting fluid streams of the first cycle process. The circulating pump is used for compression, the expansion throttle for corresponding expansion of the circulating first mixture of water and methanol, so that both the pressure and the temperature in the absorption stage are above those in the desorption stage. Compression of gaseous carbon dioxide is advantageously avoided.

The absorption stage 5 has a passage and thus at least one inlet 10 and one outlet 11 for a carbon dioxide-containing gas such as. B. an aforementioned combustion or process gas. The inlet is preferably arranged at the bottom, as shown, and the outlet at the top. It is preferably designed as a wet scrubber, i. H . it comprises an internal volume through which the gas containing carbon dioxide preferably flows from bottom to top. The aforesaid first mixture of water and methanol, on the other hand, is introduced into the interior volume at the top and penetrates it downwards in countercurrent to the through-flow and is then discharged out of the volume again at the bottom via an outlet. The first mixture is liquid and serves on the one hand as a solvent for a selective absorption of carbon dioxide from the gas containing carbon dioxide and on the other hand as a temperature-determining element for the process conditions in the absorption stage.

The desorption stage 6 , on the other hand, is not only involved in the first cycle process 1 but also in the second cycle process 2 described below. For this purpose, the desorption stage preferably has one volume, more preferably only one volume, which is equally integrated as a mixing chamber in the first and second circulatory process. The inflow 12 of the first cycle process is preferably at the top, the outlet 13 at the bottom in the volume, so that a run-through as in a wet scrubber can be implemented here. Inlet 14 for liquid components (and any residues of gases still present, i.e. residues of gases not previously separated in the first liquid-gas phase separation stage described below) and gas outlet 15 for the gaseous components of the second cycle process are preferably at the top in volume, while the liquid components of the second cycle process are taken up by the volume of the first cycle process and are discharged with this at the bottom of the volume via the outlet 13 of the first cycle process.

Furthermore, the volume has an inlet for hydrogen 16, preferably in the lower region of the volume for the connection and thus desorption of the carbon dioxide bound in the first cycle process.

Hydrogen input is preferably direct from a high pressure electrolysis (pressure is generated by pumping water rather than compressing generated H2) as a hydrogen source 17, with renewable electricity being usable. Alternatively, the hydrogen can be used from an industrial process if the hydrogen is present in a correspondingly high concentration (preferably over 98% by volume). In addition, hydrogen temperature control means 18 is provided between the high-pressure electrolysis and the inlet for hydrogen.

The first cycle process is in the liquid phase as it passes through the desorption stage 6, while the second cycle process is introduced into the desorption stage in liquid form, but is only returned from this with the gaseous component via the outlet 15 back into the second process cycle. Furthermore, in the first cycle process, an outlet 19 for the first mixture of water and methanol is provided between the desorption stage and the first heat exchanger. This is preferably the only outlet for the methanol that forms in the device from the circulatory processes. The portion of the first mixture of water and methanol branched off in this way is preferably fed to a distillation apparatus 20 for the separation of methanol and water.

The second cycle process 2 with a second circulating line 21 for a circulating second mixture of methanol, water, carbon dioxide and hydrogen passes through the aforementioned desorption stage 6 for carbon dioxide with the feed for hydrogen 16, followed by a first liquid-gas phase separation stage e 22 with a return for liquid phases 23 of the methanol and the water to the desorption as part of the second circulating line and the aforementioned gas outlet 15 and an inlet 14 from or. to the desorption stage.

Furthermore, the second cycle process shown between gas outlet 14 and liquid-gas phase separation stage 22 has a condenser 24, which is preferably provided, in which the gaseous components of water and methanol are at least partially (further) liquefied, while the carbon dioxide and hydrogen in the gaseous modi fication remain and are transferred via a gas outlet 27 of the first liquid-gas phase separation stage 22 in the third cycle process 3 described below.

The first liquid-gas phase separation stage 22 and the condenser 24 are consequently involved not only in the second cycle process 2 but also in the third cycle process 3 described below. The third cycle process 3 with a third circulating line 25 for a circulating third mixture of carbon dioxide and hydrogen comprises a methanol synthesis reactor 26 with cooling 28 , the aforementioned first liquid-gas phase separation stage 22 , the gas outlet 27 opening into the third circulating line 25 , and the third recirculating line, which opens into an inlet 29 in the liquid-gas phase separation stage 22 . The third encircling line opens out - as shown in FIG. l shown - preferably in the second circulating line 21 between the gas outlet 15 and the optional condenser 27 or the inlet 29 in the second circulating line. The third circulating line thus leads into the liquid-gas phase separation stage 22 via the second circulating line.

Furthermore, the third cycle process between the methanol synthesis reactor 26 and the first liquid-gas phase separation stage 22 runs through a second heat exchanger 30, with the third circulating line crossing in the second heat exchanger. Furthermore, there is a fluid diverter 31 as a fluid outlet 38 in the third circulating line between the methanol synthesis reactor 26 and the second heat exchanger 30 . Furthermore, a blower 32 is arranged in the gas-carrying section of the third circulating line between the second heat exchanger 30 and the inlet 29 into the first liquid-gas phase separation stage 22 , preferably the condenser 24 .

The aforementioned device can be operated in an advantageous manner in only two pressure levels, with only the absorption stage 5 in the first cycle process having to be operated in principle with an existing flue gas or process gas pressure and is preferably designed for a range from 1 to 10 bar. All management areas of the three circulatory processes Circulation pump 8 and expansion throttle 9 arranged on both sides in the first circulating line to the absorption stage are designed for a significantly higher pressure, which is adapted to the requirements of the process conditions of methanol synthesis from CO2. That is preferably uniformly in a range from 40 to 50 bar. The absorption stage 5 is preferably in a temperature range from −40° C. to 30° C., more preferably from −30° C. to 10° C., and the desorption stage 6 is preferably in a temperature range from −80° C. to 210° C., more preferably from 100°C to 180°C, more preferably between 140°C and 170°C, and the methanol synthesis reactor 26 is preferably operated in a temperature range from 180°C to 300°C, more preferably from 210°C to 260°C. The state variables shown schematically in FIG. 4 in a process flow diagram of the method according to FIG. 1 lie within these aforementioned intervals.

For maintaining and controlling the temperature in the absorption stage 5 and the desorption stage 6, a temperature control device 34 or 35 is preferably connected upstream in the first circulating line 4 before the desorption stage and/or before the absorption stage. The temperature control devices particularly influence the inlet temperatures of the circulating first mixture of water and methanol in the absorption stage and desorption stage in the first cycle process and thus the aforementioned temperatures in the absorption stage and the desorption stage. The temperature control device 34 before the absorption stage is preferably a combined cooling and heating element or a cooling element. The temperature control device 35 before the desorption stage is preferably a combined cooling and heating element or a heating element. Fig. 2 shows schematically in Fig. l illustrated exemplary embodiment, but supplemented by optional additional temperature control means for the combustion exhaust gas (or the process gas) and an equally optional additional liquid phase return to the desorption stage. Unless otherwise stated, the components not provided with reference numbers basically correspond to those shown in FIG. l with reference characters shown components.

The aforementioned temperature control means include, in particular, a third heat exchanger 33. In this, on the one hand, the carbon dioxide-containing combustion gas from a process 36 before the inlet 10 into the absorption stage, and on the other hand, a combustion gas that is routed out of the outlet 11 of the absorption stage and can be fed to a downstream flue gas cleaning system 37 can be passed through in one passage fraction each . The aim is to temper the combustion gases to the process temperature in the absorption stage before entering the absorption stage, d. H . to the aforementioned temperature range from -40 °C to 30 °C, more preferably from -30 °C to 10 °C.

The one in Fig. 2 also shown additional liquid phase return takes on the fluid outlet 38 branching off at the fluid switch 31 from the third circulation process 3 from the third circulating line 25 between the methanol synthesis reactor 26 and the second heat exchanger 30 (cf. FIG. 1). The fluid outlet opens into a liquid phase return 39 to the desorption stage 6 . More preferably, the liquid phase return itself has a feed pump 40 and/or a second liquid-gas phase separation stage 41 with a gas outlet 42 branching off from this for separating inert gas components, so that in principle only the liquid components that have been branched off can flow into the desorption stage, preferably in the upper regions. rich be returned to the desorption stage. Before the second liquid-gas phase separation stage 41, a second condenser 43 is preferably connected upstream in the liquid phase return, which brings the fluid in the liquid phase return to a temperature, preferably in the temperature range of −80° C. to 210° C., more preferably 100° C., present in the desorption stage C. to 180.degree. C., more preferably between 140.degree. C. and 170.degree. C., and thus advantageously enables a more precise material separation of the liquid phases water and methanol from the gaseous phases carbon dioxide and hydrogen.

Fig. 1 and 2 represent configurations in which the circulation pump 8 is arranged between the adsorption stage 5 and the first heat exchanger 7 .

Fig. 3 represents a further preferred embodiment of the device, which is characterized in that the first heat exchanger 7 is formed by two (or more) series-connected heat exchange elements 7a and 7b, the channels , d. H . the two sections of the first circulating lines, for two fluid fractions, penetrate the two heat exchange elements in opposite order. The line sections between the two heat exchange elements optionally serve to accommodate the circulating pump 8 and/or the expansion throttle 9.

The arrangement of the expansion throttle 9 between the absorption stage and the first heat exchanger 7 shown in all figures is preferred, since the pressure reduction and thus the temperature reduction advantageously take place after the heat transfer in the first heat exchanger.

Fig. 3 shows a preferred arrangement of the circulating pump 8 between the adsorption stage 5 and the desorption stage 6 between - Delete the two heat exchange elements 7a and 7b. This configuration has the advantage that a part of the first line upstream of the circulating pump runs through at least the first heat exchange element 7a at a lower pressure and thus temperature level and thus an increased temperature gradient and thus an increased heat transfer can be realized there. Furthermore, by dimensioning the two heat exchange elements 7a and 7b, the temperature level of the intermediate sections of the first encircling line can be adjusted exactly to a maximum possible operating temperature of the circulating pump 8 and/or the expansion throttle 9.

A configuration that is not shown in any more detail but is particularly favorable from a thermodynamic point of view provides for the circulating pump 8 to be arranged between the first heat exchanger 7 and the desorption stage 6 . In the direction of the absorption stage, the first circulating line penetrates the first heat exchanger before the expansion throttle, d. H . still with the increased pressure, i . H . increased temperature of the desorption stage. In contrast, the first circulating line in the direction of the desorption stage initially reaches the first heat exchanger with the relatively low pressure and the relatively low temperature of the absorption stage, before the pressure and temperature are further increased in the downstream circulating pump. With this configuration, an increased temperature gradient is realized in the first heat exchanger. However, the maximum operating temperature of the circulating pump limits its usability, which is why the in Fig. 3 embodiment with an arrangement of the circulating pump between the two heat exchange elements 7a and 7b is to be preferred.

The first, second and third heat exchangers and the heat exchange elements mentioned are each surface heat exchangers, each with two fluid channels or fluid channel fractions preferably counter- or cross-flow heat exchanger. A different loading of the fluid fractions in the heat exchangers excludes the use of mixed heat exchangers due to the material mixing that is naturally intended.

The ones shown in Fig. The configurations shown in FIGS. 2 and 3 can be combined with one another.

In order to carry out the method for producing methanol from carbon dioxide, a device according to one of the aforementioned embodiments is first provided. Via the inlet 10, a carbon dioxide-containing gas is passed through the absorption stage 5 and out again through the outlet 11, with the carbon dioxide preferably being taken up by a liquid first mixture of water and methanol in the first cycle process 1 at one of the pressures and temperatures mentioned for the adsorption stage will . There follows a compression and temperature control of the first mixture with the carbon dioxide in the circulating zpumpe 8 or. in the first heat exchanger 7 of the first cycle process 1 on one or. a preferably mentioned for the desorption pressure or. temperature . The arrangement of the circulating pump and the first heat exchanger has been previously discussed.

The compressed and temperature-controlled first mixture with the carbon dioxide is introduced into the desorption stage 6, with the carbon dioxide being desorbed from the first mixture and taken from the first circulatory process and with the addition of hydrogen from a circulating second mixture of methanol, water, carbon dioxide and hydrogen f is recorded in the second cycle process 2 in a range for the pressure and the temperature proposed for the desorption stage. The Kohlenstof fdioxid CO2 is thereby due to the increased temperature and over the inlet 16 at the bottom of the Desorbed desorption stage e injected hydrogen f stream from the methanol/water mixture. The hydrogen flow has two functions. On the one hand, it is used as a flushing gas and thus increases the CCh desorption in the preferably columnar volume in the desorption stage. On the other hand, it serves to introduce hydrogen as a starting material for a methanol synthesis in the methanol synthesis reactor 26, in which the carbon dioxide and the hydrogen are converted into methanol and water. For this purpose, carbon dioxide and the hydrogen are discharged from the desorption stage 6 into the second cycle process 2 via the gas outlet 15 . From there, the gases are selectively passed on to the third cycle process 3 via the first liquid-gas phase separation stage 22 as a gaseous third mixture via the gas outlet 27 . In the third cycle process, after passing through the second heat exchanger 30, it is heated and transferred to the methanol synthesis reactor 26. There, the third mixture is converted as completely as possible, but at least partially, into methanol and water.

The gaseous third mixture of hydrogen and carbon dioxide (which may still contain residual amounts of methanol and water) is preferably sprayed onto the water and methanol already formed on top of the interior volume of the methanol synthesis reactor in the direction of the outlet of the methanol synthesis reactor, with it boiling interference and accelerated conversion to water and methanol occur.

Hydrogen, H2, and carbon dioxide, CO2, react in the methanol synthesis reactor to form methanol and water. The reactor exit temperature is controlled by a countercurrent flow of some type of thermal fluid (eg, boiling water or other liquid). Temperature control at The reactor exit is important for thermodynamic reasons to maximize the yield of methanol.

The methanol and water leaving the methanol synthesis reactor 26 via an outlet arranged at the bottom in the interior volume, as well as the unreacted part of the third mixture, is then passed through the second heat exchanger 30 for temperature control, where it transfers excess heat to the mass flow of the third circulatory process 3 striving for the methanol synthesis reactor Gives mixture and is fed back into the first liquid-gas phase separation stage 22. There, the liquid components of the mixture, the methanol and the water are continuously separated and recycled via the second cycle process 2 to the desorption stage 6 and a mixture of water and methanol is continuously branched off from the desorption stage 6. The remaining, unreacted part of the The third mixture, on the other hand, is separated as a gas in the first liquid-gas phase separation stage 22 and fed back into the third cycle process and in this to the methanol synthesis reactor.

A preferred embodiment of the method also includes passing the aforementioned third mixture (H2 and CO2) and the methanol and the water through a fluid diverter 31 in the third cycle process 3 between the methanol synthesis reactor 26 and the second heat exchanger 30, with part of the third mixture, the Methanol and water is deflected into a fluid outlet 38 . This partial separation of fluid components is preferably used for the ongoing separation of undesired gaseous reaction products and impurities from the third cycle process and thus also from the methanol synthesis, which are otherwise continuously fed back as gases in the first liquid-gas phase separation stage 22 in the third cycle process, so that the process cycle could not leave and would lead to an undesirable accumulation in this.

Preferably, the part of the third mixture, the methanol and the water separated in the fluid switch is returned from the fluid outlet 38 via a liquid phase return 39 to the desorption stage 6, i.e. to the active area of the first two process circuits. More preferably, however, the part of the third mixture, the methanol and the water in the liquid phase return 39 is compressed with a feed pump 40 and/or freed from undesired gas components in particular in the second liquid-gas phase separation stage 41 .

FIG. 4 schematically shows a process flow diagram of the method in a device according to the embodiment shown in FIG. Legend 44 includes the shape symbols for several status data in the diagram: from top to bottom for the temperature in [°C] , the pressure in [bar] , the mass flow in [kg/h] and the vacuum percentage in [-] . The shape symbols can be found in the diagram in all three cycle processes 1 to 3 at various points with the status data available there. Essential components of the device are provided with the reference symbols already known from FIG.

List of references:

1 first cycle process

2 second cycle process

3 third cycle process

4 first circumferential line

5 absorption level

6 desorption stage

7 first heat exchanger

8 circulation pump

9 expansion throttle

10 Inlet for a carbon dioxide-containing gas in the absorption stage

11 Outlet for a gas containing carbon dioxide from the absorption stage

12 feed of the first circulation process in the desorption stage

13 Course of the first cycle process from the desorption stage

14 inlet for liquid components of the second cycle process in the desorption stage

15 Gas outlet from the desorption stage

16 feed for hydrogen in the desorption stage

17 hydrogen source

18 tempering agent for hydrogen f

19 Outlet for a mixture of water and methanol from the first cycle process

20 distillation apparatus

21 second circumferential line

22 first liquid-gas phase separation stage

23 Liquid phase return to the desorption stage

24 condenser

25 third circumferential line

26 methanol synthesis reactor Gas outlet from the first liquid-gas phase separation stage

cooling

Inlet to the liquid-gas phase separation stage second heat exchanger fluid separator

Blower third heat exchanger

Temperature control device before absorption stage

Temperature control device before desorption stage

process

flue gas cleaning

fluid outlet

liquid phase reflux

Feed pump second liquid-gas phase separation stage

Gas outlet from the second liquid-gas phase separation stage

Condenser in the liquid phase return

Legend of the process flow diagram

Claims

-23- Device for producing methanol from carbon dioxide, comprising a) a first circulation process (1) with a first circulating line (4) for a circulating first mixture of water and methanol, comprising i) an absorption stage (5) for carbon dioxide with a passage for a gas containing carbon dioxide, ii) a desorption stage (6) for carbon dioxide with an inlet (16) for hydrogen, iii) a first heat exchanger (7) between the absorption stage and the desorption stage, the circulating line crossing in the heat exchanger, iv) an outlet ( 19) for the first mixture of water and methanol between the desorption stage and the first heat exchanger, v) a circulation pump (8) between the absorption stage and the desorption stage and vi) an expansion throttle (9) between the first heat exchanger and the adsorption stage, b) a second cycle process (2) with a second circulating line (21) for a circulating second mixture of methanol, water, carbon dioxide and hydrogen, comprising i) the desorption stage (6) for carbon dioxide with the feed (19) for hydrogen, ii) a first liquid Gas phase separation stage (22) with a return (23) for liquid phases of the methanol and the water to the desorption stage as part of the second circulating line and iii) a gas outlet (15) from the desorption stage and an inlet (14) for the liquid phases of the methanol and the water into the desorption stage, and c) a third circulation process (3) with a third circulating line (25) for a circulating third mixture of carbon dioxide and hydrogen, comprising i) a methanol synthesis reactor (26) with cooling (28), ii) the first liquid-gas phase separation stage (22), wherein the gas outlet (27) opens into the third circulating line and the third circulating line opens into the inlet (29), iii) a second heat exchanger (30) between the methanol synthesis reactor and the first liquid-gas phase separation stage, the third circulating line in the second heat exchanger, iv) a gas outlet (31) in the third recirculating line between the methanol synthesis reactor and the second heat exchanger, v) a fan (32) between the second heat exchanger and the inlet of the first liquid-gas phase separation stage. Device according to Claim 1, characterized in that in the second and/or third circulating line (21, 25) between the desorption stage (6) or the second heat exchanger (30) on the one hand and the first liquid-gas phase separation stage (22 ) On the other hand, a capacitor (24) is provided. Device according to claim 1 or 2, characterized in that in the third circulating line (25) between the methanol synthesis reactor (26) and the second heat exchanger (30) a fluid diverter (31) is provided, with a fluid return being provided as part of the third circulating line to the second heat exchanger and a fluid outlet (38). 4. The device according to claim 3, characterized in that the fluid outlet (38) opens into a liquid phase return (39) to the desorption stage (6). 5. The device according to claim 4, characterized in that the liquid phase return (39) has a feed pump (40) and / or a second liquid-gas phase separation stage (41) with a gas outlet (42) for separating inert gas components. 6. Device according to one of the preceding claims, characterized in that the absorption stage (5) is a wet scrubber. 7. Device according to one of the preceding claims, characterized in that the desorption stage (6) comprises a volume which is integrated as a mixing chamber in the first and second cycle process (4, 21). 8. Device according to one of the preceding claims, characterized in that the first heat exchanger (7) is formed by two series-connected heat exchange elements (7a, 7b), the channels for two fluid fractions penetrating the two heat exchange elements in opposite order. 9. The device according to claim 8, characterized in that the circulation pump (8) between the adsorption stage (5) and -26- of the desorption stage (6) is arranged between the two heat exchange elements (7a, 7b). 10. Device according to one of claims 1 to 8, characterized in that the circulation pump (8) is arranged between the adsorption stage (5) and the first heat exchanger (7). 11. Device according to one of claims 1 to 8, characterized in that the circulation pump (8) is arranged between the first heat exchanger (7) and the desorption stage (6). 12. Device according to one of the preceding claims, characterized in that in the first circulating line (4) in front of the desorption stage (6) and / or in front of the absorption stage (5) in each case a temperature control device (34, 35) is connected upstream. 13. A method for producing methanol from carbon dioxide, comprising the following method steps: a) providing a device according to any one of the preceding claims 1 to 12, b) passing a carbon dioxide-containing gas through the absorption stage (5), the carbon dioxide being at a pressure between 1 and 10 bar and a temperature between -30 and 10°C by a liquid first mixture of water and methanol in the first cycle process (1), c) compression and temperature control of the first mixture with the carbon dioxide in the circulation pump (8) or in the first heat exchanger (7) of the first cycle process (1) to a pressure of between 40 and 50 bar and a temperature of between 100 and 180°C, - 27 - d) introduction of the compressed and temperature-controlled first mixture with the carbon dioxide into the desorption stage (6), the carbon dioxide being desorbed from the first mixture and taken from the first circulatory process and with the addition of hydrogen from a circulating second mixture of methanol, Water, carbon dioxide and hydrogen is absorbed in the second cycle process (2) at a pressure between 40 and 50 bar and a temperature between 100 and 180 ° C, e) forwarding of the carbon dioxide in the second cycle process (2) into the first liquid-gas Phase separation stage (22) in which a gas mixture of carbon dioxide and hydrogen is selectively diverted as the third mixture from the second to the third cycle process (3), f) heating of the gas mixture in the second heat exchanger (30) in the third cycle process to a temperature between 210 and 260 ° C, g) introduction of the temperature-controlled gas mixture into the methanol synthesis reactor (26) and partial U conversion of the third mixture into methanol and water, h) returning the third mixture, the methanol and the water through the second heat exchanger (30) into the first liquid-gas phase separation stage (22), i) separating off the liquid components of the mixture, of the methanol and the water in the first liquid-gas phase separation stage (22) and returning them via the second circulatory process (2) to the desorption stage (6) and j) continuous branching off of a mixture of water and methanol from the desorption stage (6) . A method according to claim 13, comprising passing the third mixture, the methanol and the water through a -28- Fluid switch (31) in the third cycle process (3) between the methanol synthesis reactor (26) and the second heat exchanger (30), wherein part of the third mixture, the methanol and the water is deflected into a fluid outlet (38). Method according to claim 14, characterized in that part of the third mixture, the methanol and the water from the fluid outlet (38) is returned to the desorption stage (6) via a liquid phase return (39). Process according to Claim 15, characterized in that the part of the third mixture, the methanol and the water in the liquid phase return (39) is compressed using a feed pump (40) and/or freed from gas components in a second liquid-gas phase separation stage (41). . Method according to one of Claims 13 to 16, characterized in that in the first circulating line (4) before the desorption stage (6) and/or before the absorption stage (5) there is a respective temperature control or temperature control (34, 35) in the first circulatory process ( 1) done.